RU2317501C2 - Heat exchanger for a refrigerator and a mode of manufacturing of the heat exchanger - Google Patents

Abstract

FIELD: the invention refers to heating engineering and may be used in cooling technique.

SUBSTANCE: the heat exchanger for a refrigerator has a board, a pipeline for cooling medium being in heat conducting contact with the board and a layer of a holding material bounded with the board and the pipeline. The layer of the holding material is of bituminous composition with a stuff, at that the heat capacity of the stuff is larger then the heat capacity of the bitumen. The heat exchanger is manufactured by way of forming a foot consisting of a board, a pipeline and a plate out of bituminous composition, at that out of the plate by heating and pressing the packet they form a layer of holding material. At such execution the heat exchanger may be easily utilized.

EFFECT: provides firm joining of the layers of holding material with the board.

12 cl, 5 dwg

Description

Technical field

The present invention relates to a heat exchanger, such as an evaporator, a condenser, and the like, for a refrigerator with a circuit board having heat conduit in contact with the circuit board with a refrigerant pipe and with a layer of retaining material bonded to the circuit board and the pipeline, as well as a method for manufacturing such a heat exchanger.

State of the art

A heat exchanger of this type and a method for its manufacture are known from DE 10938773 A1. In the known manufacturing method, a meander-curved pipeline is pressed against the board, and spaces between the meanders of the pipeline are filled with holding means. As such a retaining material, expandable polyurethane foam or duroplastics also having casting properties can be used. These retention materials are expensive, and the formation of a polymer network during hardening or foaming makes it difficult to return and reuse them when disposing of such an evaporator.

Disclosure of invention

An object of the present invention is to provide an inexpensive, recyclable heat exchanger for a refrigerator and a method for manufacturing it.

This problem is solved by a heat exchanger with the characteristics of paragraph 1 and a method with the characteristics of paragraph 13 of the claims.

The use of bituminous compositions for the formation of a layer of retaining material has the advantage that, on the one hand, such materials are cheap, and on the other hand, they are easily recyclable, since after disassembling such a heat exchanger into its components, the obtained bitumen material without any significant preparation and without loss of quality can be used for the manufacture of a new heat exchanger or for other purposes. In addition, the bitumen composition after cooling provides a very close contact of the pipeline with the carrier plate, thereby increasing the thermal efficiency of the heat exchanger. In addition, the mass of the bitumen composition has the ability to store heat or cold, which in the case of an evaporator helps to reduce the energy consumption of the refrigerator.

The connection of the base plate and the pipeline using a bitumen composition has great mechanical strength, and therefore the shape of the heat exchanger remains very stable when working with it in the process of large-scale production.

Owing to the tight-fitting ability of the heated bituminous composition, it exactly follows the contours of the pipeline and the carrier plate, as a result of which moisture cannot seep between the pipeline and the carrier plate, and this eliminates the risk of corrosion and the risk of separation of the pipeline from the carrier plate due to ice formation.

To improve heat transfer between the pipeline and the board, the pipeline may have a flattened section on the broadened side facing the board to provide planar contact between the board and the pipe. Thanks to the planar contact, the heat-conducting contact between the pipeline and the board is always ensured even under adverse production conditions.

In order to provide a strong bond between the layer of retaining material and the board, an adhesive layer can be preferably provided that at least partially connects the layer of retaining material to the board.

This adhesive layer preferably consists of heat activated adhesive. This simplifies the manufacture of the heat exchanger, as it allows you to pre-apply the adhesive layer without any protective measures on the plate designed to form a layer of retaining material from the bitumen composition, and this adhesive layer acquires the adhesive ability only after melting when the layer of retaining material is heated.

The bituminous composition may contain from 50 to 80% filler in addition to bitumen. The filler, in the form of a separate material or mixture of materials, can be selected based on the desire to minimize cost, increase thermal conductivity or optimize the heat capacity of the layer of retaining material. The high heat capacity leads to the fact that in the refrigerator in which the evaporator according to the invention is integrated, the compressor must work for a long time, while the temperature sensor installed on the evaporator indicates that the temperature has dropped below the lower limit at which the compressor should turn off. Conversely, it takes a long time after the compressor is turned off, while the evaporator and the inside of the refrigerator are heated to the upper limit temperature at which the compressor is turned on again. An increase in the duration of the compressor on state phase with a constant ratio of the compressor on state phase to the total operating time of the refrigerator increases the efficiency of the refrigerator.

Preferred fillers are ground stone or iron.

To protect the layer of retaining material on the side opposite the board, it can be coated with a layer of varnish.

The recommended average thickness of the layer of retaining material is in the range from 0.5 to 2 mm, preferably from 1.0 to 1.5 mm.

The manufacture of a heat exchanger of the type described above can be carried out in a simple way by forming a stack consisting of a stack consisting of a board, a refrigerant pipe and a plate of bitumen composition, and then heating the plate and compressing the stack.

Brief List of Drawings

Other features and advantages of the invention result from the following description of exemplary embodiments with reference to the accompanying drawings. The drawings show:

figure 1 is a perspective projection of the invention of the evaporator;

figure 2 - cutout in the evaporator of figure 1; and

figure 3-5 - the steps of the proposed method of manufacturing an evaporator.

Disclosure of invention

The evaporator shown in FIG. 1 in a perspective projection consists of a flat board 1 of aluminum sheet on which a refrigerant pipe 2 is placed, consisting of an aluminum tube bent in the form of meanders. The board 1 and the refrigerant pipe 2 are coated with a layer 3 of retaining material from a bitumen composition.

The bitumen composition consists of approximately 25% by weight of polymer-modified bitumen, 3% by weight of polymer and 72% by weight of stone flour as a filler. Typically, the proportion of crushed stone may be from 50 to 80% by weight. If we take the density of bitumen 1100 kg / m ³ and the density of crushed stone 2800 kg / m ³ , then this corresponds to the volumetric content of stone flour from 28 to 61%. A typical value of the specific heat S of dense natural stone used as a starting material for the preparation of stone flour is about 700 J / m ³ K, while for bitumen S ≈ 515 J / m ³ K. The specific heat of a layer of retaining material containing 72% by weight of stone powder (which corresponds to approximately 50% by volume) can be taken equal to about 610 J / m ³ K. Thus, the heat capacity of the retaining material layer is almost 20% higher than the specific heat retaining material layer of the same thickness, coc oyaschego only bitumen. At the same time, the cost of the material for the layer containing stone flour is reduced.

In particular, some metals, such as zinc (S = 785 J / m ³ K), copper (S = 995 J / m ³ K) and iron (S = 1015) have a higher heat capacity than stone, in particular -1080 J / m ³ K). Due to the particularly high heat capacity, and also taking into account the cost, iron can be considered as a filler for a layer of retaining material. Such a filler may be added to the bitumen in equal parts by volume, as indicated above. For a retaining layer containing 50% iron by volume, the thermal conductivity is S≈775 J / m ³ K.

As shown in FIG. 2, the refrigerant pipe 2 does not have a perfectly round, but flattened (flattened) cross-section, so that the refrigerant pipe 2 and the board 1 abut against each other at least approximately in the plane. This makes it possible in a technologically simple way to make heat-conducting contact between the refrigerant pipe 2 and the board 1. The retaining material layer 3 enters the sinuses 4 lying on both sides of the contact line between the refrigerant pipe 2 and the board 1. The massive retaining material layer 3 provides better heat transfer between the board 1 and refrigerant piping 2 than would be possible with the usual use of polyurethane foam as a retaining material. Due to the flattened shape of the refrigerant pipe 2, the thickness of the retaining material layer 3 in the sinuses 4 is less than would be the case with the round pipe 2. This also favors efficient heat transfer between the board 1 and the refrigerant pipe 2. Between the layer 3 of the retaining material and the board 1, there is a hot-melt adhesive layer 5, which, due to its significantly smaller thickness, is only shown as a line in FIG.

Individual operations for the manufacture of the inventive evaporator are shown in FIGS. 3-5.

In the first operation of the technological process depicted in figure 3, a package is created, which is a stack, the layers of which consist of a board 1, a refrigerant pipe 2 and a plate 6 with a thickness of 1.2 mm from a bitumen composition. On the lower side of the plate 6, facing the circuit board 1 and the refrigerant pipe 2, there is an adhesive layer 5. Since the adhesive layer 5 does not have adhesive ability with a cold plate, the plate 6 together with the layer 5 can be pre-prepared and handled without problems, not taking no action to protect the adhesive layer between the manufacture and use of the plate 6.

In the manufacturing phase of the evaporator shown in FIG. 3, the refrigerant pipe 2 does not yet have to abut the board 1 over its entire length; a slight undulation of the refrigerant pipe 2 vertically with respect to the surface of the board 1, as shown in FIG. 3, is permissible.

When depicted in figure 4, the second operation of manufacturing the evaporator to the surface of the plate 6 is pressed stamp 7. At this stage, the plate 6 is cold, and therefore hard; as a result of the pressure of the stamp 7, the refrigerant pipe 2 is pressed against the board 1 along the entire length.

On the lower side of the stamp 7, facing the plate 6, there are channels 9, the location of which corresponds to the course of the refrigerant pipe 2. Alternatively, the stamp 7 may also be made of a synthetic elastomer, for example silicone, with a hardness of, for example, 20 Shore A, with a material thickness of 20 mm. When stamping from a synthetic elastomer with a Shore hardness selected that does not cause damage to the refrigerant pipe, it is not necessary to apply channels on the underside of the stamp.

As a result of subsequent heating, the bitumen of the plate 6 becomes fluid, and the plate 6 in the spaces 8 between adjacent sections of the refrigerant pipe 2 is pressed against the board 1. The viscosity of the bitumen composition is selected so that, on the one hand, it is sufficiently fluid to penetrate the sinuses 4 between board 1 and the refrigerant pipe 2, and on the other hand, remained viscous enough to prevent the possible detachment of portions of the refrigerant pipe 2 from the board in separate places.

In order to exclude the possibility of local delamination of the refrigerant pipe 2, regardless of the fluidity of the bitumen composition, the channels 9 of the stamp 7 can be equipped with local protrusions (not shown in the drawing), which, when the plate 6 is heated, are pressed through it and are directly in contact with the refrigerant pipe 2, pressing it to the board one.

The melting temperature of the hot melt adhesive in the layer is selected so that it 5 melts during heating and molding of the plate 6, and then after cooling it firmly connects the hardened layer 3 of the retaining material with the board 1 and the refrigerant pipe 2. The lower side of the plate 6 may be covered with an adhesive layer 5 in whole or in part.

In order to seal the open surface of the retaining material layer 3, a varnish layer may be applied thereon, especially based on shellac.

Removing the bituminous composition during disposal of the evaporator is simple: when the evaporator is deformed, the cold-brittle layer of retaining material breaks into pieces or by strong cooling of the evaporator, for example using dry ice, the connection between the carrier layer 3 and the refrigerant pipe 2 and board 1 breaks.

Claims (12)

1. A heat exchanger for a refrigerator comprising a board (1) in heat-conducting contact with the board (1) a refrigerant pipe (2) and a retaining material layer (3) bonded to the duct (2), characterized in that the retaining material layer consists of bituminous composition with a filler, and the filler has a heat capacity greater than the heat capacity of bitumen. 2. A heat exchanger according to claim 1, characterized in that the refrigerant pipe (2) has a flattened section. 3. The heat exchanger according to claim 1 or 2, characterized in that the layer (3) of the retaining material is connected to the board (1) with an adhesive layer (5). 4. The heat exchanger according to claim 3, characterized in that the adhesive layer (5) consists of adhesive activated by high temperature. 5. The heat exchanger according to claim 1, characterized in that the filler content in the bitumen composition is from 50 to 80 wt.%. 6. The heat exchanger according to claim 1, characterized in that the filler content in the bitumen composition is from 25 to 65 vol.%. 7. The heat exchanger according to claim 1, characterized in that the crushed stone is used as a filler. 8. The heat exchanger according to claim 1, characterized in that iron is used as the filler. 9. The heat exchanger according to claim 1, characterized in that on the opposite board (1) the side of the layer (3) of the retaining material is applied a varnish layer. 10. The heat exchanger according to claim 1, characterized in that the average thickness of the layer of retaining material (3) is from 0.5 to 2 mm, and preferably from 1.0 to 1.5 mm. 11. A method of manufacturing a heat exchanger, in particular an evaporator or condenser, as claimed in any of the preceding paragraphs, comprising the following operations: form a stack consisting of a board (1), a pipeline (2) for the refrigerant and a plate (6) of a bitumen composition, heat the plate (6) and compress the foot. 12. The method according to claim 11, characterized in that the board (1), the pipeline (2) and the plate (6) of the bitumen composition are stacked in the specified order.

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